Hovering and touch sensing apparatus with auxiliary capacitance-exciting signal

ABSTRACT

A hovering and touch sensing apparatus with auxiliary capacitance-exciting signal includes a plurality of touch sensing electrodes, a system circuit and a touch control circuit. When an operating object approaches or touches the touch sensing electrodes for hovering or touch sensing, there is no common circuit loop between the system circuit and the touch-sensing circuit to prevent the influence of the system circuit to the touch control circuit. The touch control circuit sends a capacitance-exciting signal to the operating object through a first specific conductor. The touch control circuit sends an auxiliary capacitance-exciting signal to a selected touch-sensing electrode and a touch-sensing circuit receives a touch sensing signal from the selected touch-sensing electrode.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a sensing apparatus, especially to ahovering and touch sensing apparatus with auxiliary capacitance-excitingsignal and having enhanced sensitivity.

Description of Prior Art

The popularity of the mobile electronic devices boosts the developmentof touch control technologies. The mutual interference between thedisplay circuit and the touch control circuit in panel display is importissue as the touch control panel become thinner and more compact.Moreover, the mobile electronic devices may have demand for 3D gesturetouch control in the near future. Therefore, the signal to noise ratioof capacitance measurement is desirably to enhance to increase themeasurement distance between stylus (user finger) and mobile electronicdevice. There is still much room for improvement for touch controldevices.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a hovering and touchsensing apparatus with auxiliary capacitance-exciting signal and havingenhanced sensitivity.

Accordingly, the present invention provides a hovering and touch sensingapparatus with auxiliary capacitance-exciting signal, the hovering andtouch sensing apparatus comprising hovering and touch sensing apparatuswith auxiliary capacitance-exciting signal, the hovering and touchsensing apparatus comprising:

a touch sensing electrode matrix comprising a plurality of touch sensingelectrodes, a system circuit and a touch control circuit;

the system circuit comprising: a system power source; a system ground; afirst specific conductor with area larger than any area of the touchsensing electrodes, the first specific conductor electrically connectedto the system power source and the system ground;

the touch control circuit comprising: a touch control power source; atouch control ground; a capacitance-exciting signal source; acapacitance-exciting signal driver circuit; an auxiliarycapacitance-exciting signal driver circuit and at least onecapacitance-sensing signal receiving circuit, wherein the touch controlpower source is electrically connected to the touch control ground andsupplies electric power to the capacitance-exciting signal source, thecapacitance-exciting signal driver circuit, the auxiliarycapacitance-exciting signal driver circuit and the at least onecapacitance-sensing signal receiving circuit,

wherein when an operation object approaches or touches the plurality oftouch sensing electrodes for hovering or touch sensing operation, thereis no common current loop between the system power source and the touchcontrol power source; the capacitance-exciting signal source generatesan alternating signal; the capacitance-exciting signal driver circuitprocesses the alternating signal and then electrically coupled theprocessed alternating signal to the first specific conductor, theauxiliary capacitance-exciting signal driver circuit generates anauxiliary capacitance-exciting signal and applies the auxiliarycapacitance-exciting signal to a selected touch sensing electrode;

wherein a first capacitor is formed between the operation object and thefirst specific conductor, a second capacitor is formed between theoperation object and the respective one of the touch sensing electrodes,the at least one capacitance-sensing signal receiving circuit receives atouch sensing signal from the selected touch sensing electrode.

BRIEF DESCRIPTION OF DRAWING

The features of the invention believed to be novel are set forth withparticularity in the appended claims. The invention itself, however, maybe best understood by reference to the following detailed description ofthe invention, which describes an exemplary embodiment of the invention,taken in conjunction with the accompanying drawings, in which:

FIG. 1 shows a block diagram of the hovering and touch sensing apparatusaccording to an embodiment of the present invention.

FIG. 2 shows a block diagram of the hovering and touch sensing apparatusaccording to another embodiment of the present invention.

FIG. 3 shows a block diagram of the hovering and touch sensing apparatusaccording to still another embodiment of the present invention.

FIG. 4 shows a block diagram of the hovering and touch sensing apparatusaccording to still another embodiment of the present invention.

FIG. 5A shows a block diagram of the hovering and touch sensingapparatus according to still another embodiment of the presentinvention.

FIG. 5B shows a block diagram of the hovering and touch sensingapparatus according to still another embodiment of the presentinvention.

FIG. 6 shows a block diagram of the hovering and touch sensing apparatusaccording to still another embodiment of the present invention.

FIG. 7 shows a block diagram of the hovering and touch sensing apparatusaccording to still another embodiment of the present invention.

FIG. 8 shows a block diagram of the hovering and touch sensing apparatusaccording to still another embodiment of the present invention.

FIG. 9 is a sectional view showing the hovering and touch sensingapparatus according to one embodiment of the present invention.

FIG. 10A is a top view showing the touch sensing electrode layer of thehovering and touch sensing apparatus according to an embodiment of thepresent invention.

FIG. 10B is a schematic view showing the signals applied to the hoveringand touch sensing apparatus during hovering or touch sensing operations.

FIG. 11 is a sectional view showing the hovering and touch sensingapparatus 10 according to another embodiment of the present invention.

FIG. 12A shows a layered structure of the hovering and touch sensingapparatus according to an embodiment of the present invention.

FIG. 12B shows the layered structures for the touch control panelaccording to an embodiment of the present invention.

FIG. 12C shows the layered structures for the touch control panelaccording to another embodiment of the present invention.

FIG. 12D shows the layered structures for the touch control panelaccording to still another embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 9 is a sectional view showing the hovering and touch sensingapparatus 10 according to one embodiment of the present invention. Thehovering and touch sensing apparatus 10 comprises, from top to bottom, aprotection layer 100, a touch sensing electrode layer 102, anencapsulation layer 104, a common electrode layer 106, an organic lightemitting material layer 110, a thin film transistor (TFT) substrate 120,a shielding protective layer 204, a circuit layer 202 and a metalliccasing 200 (or a conductive coating 200′ of a casing). Besides, the TFTsubstrate 120 further comprises a pixel electrode layer 130, a TFT layer128 and a transistor substrate 126. The organic light emitting materiallayer 110 comprises a plurality of organic light emitting materials 162.The organic light emitting materials 162 shown in FIG. 9 may emit lightwith different colors, for example, red color, green color and bluecolor. However, according to another embodiment, the organic lightemitting materials 162 shown in FIG. 9 may also emit light with the samecolor. Besides, the display circuit corresponding to the embodimentshown in FIG. 9 is organic light emitting display circuit. However,according to the present invention, the display circuit may also beliquid crystal display circuit or micro LED display circuit.

With reference also to FIG. 9, the pixel electrode layer 130 comprises aplurality of pixel electrodes 172 and the TFT layer 128 comprises aplurality of thin film transistors 174, where the pixel electrodes 172are respectively corresponding to the thin film transistors 174. Theelectric polarity of the pixel electrodes 172 is opposite to theelectric polarity of common electrode layer 106. For example, the commonelectrode layer 106 is cathode when the pixel electrodes 172 are anodes;the common electrode layer 106 is anode when the pixel electrodes 172are cathodes. The thin film transistors 174 are arranged on thetransistor substrate 126. The transistor substrate 126 further comprisesa plurality of gate lines 132 and a plurality of data lines 134, wherethe gate lines 132 and the data lines 134 are respectively connected tothe gates and sources (drains) of the corresponding thin filmtransistors 174. Moreover, the embodiment shown in FIG. 9 iscorresponding to the hovering and touch sensing apparatus 10 applying tothe electronic system with organic light emitting display device.However, the hovering and touch sensing apparatus 10 of the presentinvention may also apply to the electronic system with other kinds ofdisplay devices, so the organic light emitting material layer 110 andthe TFT substrate 120 may also have corresponding modification orreplacement. Therefore, the detailed structure shown in FIG. 9 is notlimitation to the present invention. As shown in FIG. 9, if an operationobject (such as user finger or stylus) approaches or touches the touchsensing electrodes of the touch sensing electrode layer 102 for hoveringor touch control operation, a capacitance-exciting signal Vs is appliedto a larger conductor (larger than one of the touch sensing electrodesof the touch sensing electrode layer 102). The larger conductor is forexample, the common electrode layer 106 shown in FIG. 9 such that thecapacitance-exciting signal Vs is more effectively applied to theoperation object to enhance the measurement sensibility and signal tonoise ratio. Besides, for the sake of description convenience, in abovedescription, the operation object (such as user finger or stylus) isdescribed to approach or touch the touch sensing electrodes of the touchsensing electrode layer 102. However, in actual operation, withreference also to FIG. 9, the operation object may touch the insulatingprotection layer 100 and the statics on the operation object aretransmitted to the touch sensing electrode layer 102 through theprotection layer 100. In terms of touch control, the operation objectequivalently “touches” the touch sensing electrode layer 102 for touchcontrol operation. Besides, if the operation object is close to(approaches) the hovering and touch sensing apparatus 10 according tothe present invention but is not in contact with the hovering and touchsensing apparatus 10, equivalent capacitor with larger capacitance canbe formed between the common electrode layer 106 and the operationobject because the common electrode layer 106 has larger area.Therefore, the capacitance-exciting signal Vs is more effectivelyapplied to the operation object. The operation object has prominentstatic change and the touch sensing electrodes of the touch sensingelectrode layer 102 may more effectively sense the signals correspondingto the static change. Therefore, the hovering and touch sensingapparatus 10 according to the present invention can also preciselydetermine whether an operation object is close to (approaches) theretofor hovering sensing operation.

FIG. 11 is a sectional view showing the hovering and touch sensingapparatus 10 according to another embodiment of the present invention.The hovering and touch sensing apparatus 10 comprises, from top tobottom, a protection layer 100, a touch sensing electrode layer 102, anupper polarizer layer 182, a color filter plate 140, a static shieldingprotective layer 150, a liquid crystal material layer 111, a TFTsubstrate 120, a lower polarizer layer 184, and a metallic casing 200(or a conductive coating 200′ of a casing). Besides, the TFT substrate120 further comprises a pixel electrode layer 130, a common electrodelayer 106, a TFT layer 128 and a transistor substrate 126. The colorfilter plate 140 comprises a color filter (CF) substrate 141, a blackmatrix layer 142 and a color filter layer 143.

With reference also to FIG. 11, the pixel electrode layer 130 comprisesa plurality of pixel electrodes 172 and the TFT layer 128 comprises aplurality of thin film transistors 174, where the pixel electrodes 172are respectively corresponding to the thin film transistors 174. Withreference also to FIG. 11, if an operation object (such as user fingeror stylus) approaches or touches the touch sensing electrodes of thetouch sensing electrode layer 102 for touch control operation, acapacitance-exciting signal Vs is applied to a larger conductor (largerthan one of the touch sensing electrodes of the touch sensing electrodelayer 102). The larger conductor is for example, the static shieldingprotective layer 150 shown in FIG. 11 such that the capacitance-excitingsignal Vs is more effectively applied to the operation object to enhancethe measurement sensibility and signal to noise ratio. Besides, for thesake of description convenience, in above description, the operationobject (such as user finger or stylus) is described to approach or touchthe touch sensing electrodes of the touch sensing electrode layer 102.However, in actual operation, with reference also to FIG. 11, theoperation object may touch the insulating protection layer 100 and thestatic on the operation object is transmitted to the touch sensingelectrode layer 102 through the protection layer 100. In terms of touchcontrol, the operation object equivalently “touches” the touch sensingelectrode layer 102 for touch control operation. Besides, if theoperation object is close to (approaches) the hovering and touch sensingapparatus 10 according to the present invention but is not in contactwith the hovering and touch sensing apparatus 10, an equivalentcapacitor with larger capacitance can be formed between the staticshielding protective layer 150 and the operation object because thestatic shielding protective layer 150 has larger area. Therefore, thecapacitance-exciting signal Vs is more effectively applied to theoperation object and the operation object has prominent static change.The touch sensing electrodes of the touch sensing electrode layer 102may more effectively sense the signals corresponding to the staticchange. Therefore, the hovering and touch sensing apparatus 10 accordingto the present invention can also precisely determine whether anoperation object is close to (approaches) thereto for hovering sensingoperation.

FIG. 10A is a top view showing the touch sensing electrode layer 102 ofthe hovering and touch sensing apparatus 10 according to an embodimentof the present invention. FIG. 10B is a schematic view showing thesignals applied to the hovering and touch sensing apparatus 10 duringhovering or touch sensing operations. As shown in FIG. 10A, the touchsensing electrode layer 102 of the hovering and touch sensing apparatus10 has a touch sensing electrode array, where the touch sensingelectrode array comprises a plurality of touch sensing electrodes Enarranged in array fashion. For the sake of description convenience, thetouch sensing electrodes shown in FIG. 10B are labeled with symbolsE1˜E8, and FIG. 10B only shows part of the touch sensing electrodes insectional view. Besides, for the sake of following description, thetouch sensing electrode E4 is also referred to as the selected touchsensing electrode Es and the touch sensing electrodes surrounding theselected touch sensing electrode Es are referred to as the surroundingtouch sensing electrodes Em. With reference back to FIG. 10B, whenperforming hovering or touch sensing operations to the hovering andtouch sensing apparatus 10, a touch control circuit 50 sends acapacitance-exciting signal to a first specific conductor (withreference to FIG. 9, the first specific conductor may be the commonelectrode layer 106) and then receives (reads) a touch sensing signal Vcfrom the selected touch sensing electrode E4 (Es). Besides, the touchcontrol circuit 50 optionally sends an auxiliary signal Va to thesurrounding touch sensing electrodes Em, this will be detailed later.

FIG. 1 shows a block diagram of the hovering and touch sensing apparatus10 according to an embodiment of the present invention. As shown in thisfigure, the hovering and touch sensing apparatus 10 of the presentinvention further comprises a touch control circuit 50 and a systemcircuit 60. The touch control circuit 50 comprises a touch control powersource 500, a touch control ground 502, a capacitance-exciting signaldriver circuit 510, a capacitance-exciting signal source 512 and atleast one capacitance-sensing signal receiving circuit 520. The systemcircuit 60 comprises a system power source 600, a system ground 602 anda first specific conductor Sz1, where the touch control ground 502 andthe system ground 602 are different grounds and depicted with differentsymbols. In the touch control circuit 50, even though not clearlylabeled, the inverted-triangle symbols indicate the same ground and thisis applied to the following drawings. During hovering or touch sensingoperation, the capacitance-exciting signal source 512 generates analternating signal (such as sinusoid wave signal, square wave signal,triangular wave signal or trapezoid wave signal) and the alternatingsignal is processed by the capacitance-exciting signal driver circuit510 to form the capacitance-exciting signal Vs. The touch controlcircuit 50 sends the capacitance-exciting signal Vs to the firstspecific conductor Sz1 through, for example, a resistor or a capacitor.If an operation object (such as user finger or stylus) approaches ortouches the hovering and touch sensing apparatus 10, for example,approaches or touches the protection layer 100 (as mentioned above, totouch the insulating protection layer 100 is equivalent to touch thetouch sensing electrode layer 102 in terms of capacitance sensing), afirst capacitor C1 is formed between the first specific conductor Sz1and the operation object. According to one possible implementation, thefirst specific conductor Sz1 may be the static shielding protectivelayer 150, the shielding protective layer 204 of a display, a commonelectrode layer of a display (such as the common electrode layer 106shown in FIG. 9 or FIG. 11), a metallic casing 200 or a conductivecoating 200′ of a casing. Moreover, a second capacitor C2 is formedbetween the operation object and the respective touch sensing electrode.The capacitance-sensing signal receiving circuit 520 then receives(reads) a touch sensing signal Vc from the selected touch sensingelectrode E4 (Es). The size of the first specific conductor Sz1 isgenerally much larger than the size of the touch sensing electrode (forexample, ten times larger or much larger), the capacitance of the firstcapacitor C1 is much larger than the capacitance of the second capacitorC2 (for example, ten times larger or much larger). Therefore, thereceiving result (for measuring the capacitance of the second capacitorC2) of the capacitance-sensing signal receiving circuit 520 is notinfluenced as the signal path is the first capacitor C1 in series withthe operation object and the second capacitor C2. Moreover, as the firstcapacitor C1 has larger capacitance, the capacitance-exciting signal Vscan be more effectively sent from the first specific conductor Sz1 tothe operation object, thus enhance the preciseness of the hovering ortouch sensing operation.

Moreover, with reference to FIG. 1, during the hovering or touch sensingoperation, there is only one physical connection point between the touchcontrol circuit 50 and the system circuit 60, namely, a singleconnection point connected to the first specific conductor Sz1, and thetouch control ground 502 and the system ground 602 are differentgrounds. Therefore, there is no common current loop between the touchcontrol circuit 50 and the system circuit 60 during the hovering ortouch sensing operation of the hovering and touch sensing apparatus 10.Moreover, the measurement of the touch control circuit 50 will not beinfluenced by the noise from the system circuit 60. The system powersource 600 has larger capacity to supply electric power to the pixelelectrode 172, the common electrode layer 106, and the thin filmtransistors 174 shown in FIG. 9 or the backlight unit; therefore, thesystem power source 600 has larger power noise. During the hovering ortouch sensing operation, the noise of the system circuit 60 (includingdisplay circuit) can be prevented from coupling to the touch controlcircuit 50 and from influencing the sensing result of the touch controlcircuit 50 if there is no common current loop between the touch controlcircuit 50 and the system circuit 60.

FIG. 2 shows a block diagram of the hovering and touch sensing apparatus10 according to another embodiment of the present invention. Thehovering and touch sensing apparatus 10 in FIG. 2 is similar to thatshown in FIG. 1; however, the hovering and touch sensing apparatus 10 inFIG. 2 further comprises a DC power source 530 and two switches 532 and534, where the ground of the DC power source 530 is also the touchcontrol ground 502. During hovering or touch sensing operations, the twoswitches 532 and 534 are operated to turn on or off such that a DCvoltage is applied to a second specific conductor Sz2. The secondspecific conductor Sz2 is a conductor different with the first specificconductor Sz1 and structurally placed between the first specificconductor Sz1 and the touch sensing electrode layer 102. With referencealso to FIG. 9, if the first specific conductor Sz1 is the metalliccasing 200 or the conductive coating 200′ of the casing, then the secondspecific conductor Sz2 may be the shielding protective layer 204 of thedisplay or the common electrode layer (common anode or common cathode)106 of OLED display. If the first specific conductor Sz1 is theshielding protective layer 204 of the display, then the second specificconductor Sz2 may be the common electrode layer 106 of OLED display.

With reference also to FIG. 11, if the first specific conductor Sz1 isthe metallic casing 200 or the conductive coating 200′ of the casing,then the second specific conductor Sz2 may be the static shieldingprotective layer 150 of the display or the common electrode layer 106 ofLCD. If the first specific conductor Sz1 is the common electrode layer106 of LCD, then the second specific conductor Sz2 may be the staticshielding protective layer 150 of the display.

The second specific conductor Sz2 is structurally placed between thefirst specific conductor Sz1 and the touch sensing electrode layer 102.If a DC voltage is applied to the second specific conductor Sz2, thedirect signal coupling between the first specific conductor Sz1 and theselected touch sensing electrode Es can be blocked to enhance thepreciseness for hovering or touch sensing operations. According toanother possible implementation of the present invention, the secondspecific conductor Sz2 may be electrically connected with the touchcontrol ground 502. Namely, by turning off the switch 532 and turning onthe switch 534, the second specific conductor Sz2 is electricallyconnected to the touch control ground 502 such that the direct signalcoupling between the first specific conductor Sz1 and the selected touchsensing electrode Es can be blocked to enhance the preciseness forhovering or touch sensing operations.

FIG. 3 shows a block diagram of the hovering and touch sensing apparatus10 according to still another embodiment of the present invention. Thehovering and touch sensing apparatus 10 in FIG. 3 is similar to thatshown in FIG. 1; however, the hovering and touch sensing apparatus 10 inFIG. 3 further comprises an amplifier with gain larger than zero(namely, non-inverting amplifier) 540. The input of the amplifier 540with gain larger than zero is coupled to the selected touch sensingelectrode Es and the capacitance-sensing signal receiving circuit 520,while the output of the amplifier 540 with gain larger than zero iscoupled to the surrounding touch sensing electrodes Em arranged aroundthe selected touch sensing electrode Es. The amplifier 540 with gainlarger than zero receives the touch sensing signal Vc and non-invertingamplifies the touch sensing signal Vc to form an auxiliary signal Va forpreventing signal coupling. The amplifier 540 with gain larger than zerofurther applies the auxiliary signal Va to the surrounding touch sensingelectrodes Em around the selected touch sensing electrode Es such thatthe coupling signal from user finger (or stylus) can be prevented fromcoupling to the selected touch sensing electrode Es through thesurrounding touch sensing electrodes Em, thus prevent the couplingsignal from influencing the measurement for the selected touch sensingelectrode Es. Besides above way to apply the auxiliary signal Va, thetouch control circuit 50 may send a zero-level signal or a DC signal tothe surrounding touch sensing electrodes Em arranged around the selectedtouch sensing electrode Es. Similarly, the coupling signal from userfinger (or stylus) can be prevented from coupling to the selected touchsensing electrode Es through the surrounding touch sensing electrodesEm, thus prevent the coupling signal from influencing the measurementfor the selected touch sensing electrode Es. In this situation, theamplifier 540 with gain larger than zero (non-inverting amplifier 540)can be replaced by an amplifier with gain equal to zero to provide thezero-level signal.

FIG. 4 shows a block diagram of the hovering and touch sensing apparatus10 according to still another embodiment of the present invention. Thehovering and touch sensing apparatus 10 in FIG. 4 is similar to thatshown in FIG. 2; however, the hovering and touch sensing apparatus 10 inFIG. 4 further comprises an amplifier with gain larger than zero(namely, non-inverting amplifier) 540 in comparison with the embodimentshown in FIG. 2. Similarly, the input of the amplifier 540 with gainlarger than zero is coupled to the selected touch sensing electrode Esand the capacitance-sensing signal receiving circuit 520, while theoutput of the amplifier 540 with gain larger than zero is coupled to thesurrounding touch sensing electrodes Em arranged around the selectedtouch sensing electrode Es. When the hovering and touch sensingapparatus 10 performs hovering or touch sensing operations, thecapacitance-exciting signal source 512 of the touch control circuit 50generates an alternating signal and the alternating signal is processedby the capacitance-exciting signal driver circuit 510 to form thecapacitance-exciting signal Vs. The touch control circuit 50 sends thecapacitance-exciting signal Vs to the first specific conductor Sz1 suchthat a first capacitor C1 is formed between the first specific conductorSz1 and the operation object. Moreover, a second capacitor 2 is formedbetween the operation object and the respective touch sensing electrode.The capacitance-sensing signal receiving circuit 520 then receives(reads) a touch sensing signal Vc from the selected touch sensingelectrode Es. At this time, the DC power source 530 supplies a DCvoltage to the second specific conductor Sz2. The second specificconductor Sz2 is a conductor different with the first specific conductorSz1 and structurally placed between the first specific conductor Sz1 andthe touch sensing electrode layer 102. The direct signal couplingbetween the first specific conductor Sz1 and the selected touch sensingelectrode Es can be blocked to enhance the preciseness for hovering ortouch sensing operations. The amplifier 540 with gain larger than zeroreceives the touch sensing signal Vc and non-inverting amplifies thetouch sensing signal Vc to form an auxiliary signal Va for preventingsignal coupling. The amplifier 540 with gain larger than zero furtherapplies the auxiliary signal Va to the surrounding touch sensingelectrodes Em arranged around the selected touch sensing electrode Essuch that the coupling signal from user finger (or stylus) can beprevented from coupling to the selected touch sensing electrode Esthrough the surrounding touch sensing electrodes Em, thus prevent thecoupling signal from influencing the measurement for the selected touchsensing electrode Es. Besides above way to applying the auxiliary signalVa, the touch control circuit 50 may send a zero-level signal or a DCsignal to the surrounding touch sensing electrodes Em arranged aroundthe selected touch sensing electrode Es. Similarly, the coupling signalfrom user finger (or stylus) can be prevented from coupling to theselected touch sensing electrode Es through the surrounding touchsensing electrodes Em, thus prevent the coupling signal from influencingthe measurement for the selected touch sensing electrode Es.

Similarly, in the embodiments shown in FIGS. 2 to 4, during hovering ortouch sensing operations, there is only one physical connection pointbetween the touch control circuit 50 and the system circuit 60, namely,a single connection point connected to the first specific conductor Sz1,and the touch control ground 502 and the system ground 602 are differentgrounds. Therefore, there is no common current loop between the touchcontrol circuit 50 and the system circuit 60 during the hovering ortouch sensing operation of the hovering and touch sensing apparatus 10.Moreover, the measurement of the touch control circuit 50 will not beinfluenced by the noise from the system circuit 60. Besides, a groundimpedance Z1 is present between the first specific conductor Sz1 and thesystem ground 602, and the ground impedance Z1 is for example, animpedance smaller than one hundred thousand of ohms or a zero-ohmimpedance.

FIG. 5A shows a block diagram of the hovering and touch sensingapparatus 10 according to still another embodiment of the presentinvention. Similarly, the sectional view of the hovering and touchsensing apparatus 10 shown in FIG. 5A can be referred to that shown inFIG. 9, while the distribution of the touch sensing electrodes can bereferred to those shown in FIGS. 10A and 10B. As shown in FIG. 5A, thehovering and touch sensing apparatus 10 of the present invention furthercomprises a touch control circuit 50 and a system circuit 60. The touchcontrol circuit 50 comprises a touch control power source 500, a touchcontrol ground 502, a capacitance-exciting signal driver circuit 510, acapacitance-exciting signal source 512 and at least onecapacitance-sensing signal receiving circuit 520. The system circuit 60comprises a system power source 600, a system ground 602 and a firstspecific conductor Sz1, where the touch control ground 502 and thesystem ground 602 are different grounds and depicted with differentsymbols. Besides, the touch control circuit 50 further comprises anauxiliary capacitance-exciting signal source 552 connected to the touchcontrol ground 502 and an auxiliary capacitance-exciting signal drivercircuit 550.

During hovering or touch sensing operation, the capacitance-excitingsignal source 512 generates an alternating signal (such as sinusoid wavesignal, square wave signal, triangular wave signal or trapezoid wavesignal) and the alternating signal is processed by thecapacitance-exciting signal driver circuit 510 to form thecapacitance-exciting signal Vs. The touch control circuit 50 sends thecapacitance-exciting signal Vs to the first specific conductor Sz1through, for example, a resistor or a capacitor. If an operation object(such as user finger or stylus) approaches or touches the hovering andtouch sensing apparatus 10, for example, approaches or touches theinsulating protection layer 100, a first capacitor C1 is formed betweenthe first specific conductor Sz1 and the operation object. According toone possible implementation, the first specific conductor Sz1 may be thestatic shielding protective layer 150, the shielding protective layer204 of a display, a common electrode layer of a display (such as thecommon electrode layer 106 shown in FIG. 9 or FIG. 11), a metalliccasing 200 or a conductive coating 200′ of a casing.

At the same time, the auxiliary capacitance-exciting signal source 552generates another alternating signal and the auxiliarycapacitance-exciting signal driver circuit 550 processes above-mentionedanother alternating signal into an auxiliary capacitance-exciting signalVs1. The auxiliary capacitance-exciting signal driver circuit 550 sendsthe auxiliary capacitance-exciting signal Vs1, through an impedance Z2,to the selected touch sensing electrode Es. The impedance Z2 is forexample, a resistor, a capacitor or a conductive wire. A secondcapacitor C2 is formed between the operation object and the respectivetouch sensing electrode. The capacitance-sensing signal receivingcircuit 520 then receives (reads) a touch sensing signal Vc from theselected touch sensing electrode E4 (Es). The size of the first specificconductor Sz1 is generally much larger than the size of the touchsensing electrode (for example, ten times larger or much larger), thecapacitance of the first capacitor C1 is much larger than thecapacitance of the second capacitor C2 (for example, ten times larger ormuch larger). Therefore, the receiving result (for measuring thecapacitance of the second capacitor C2) of the capacitance-sensingsignal receiving circuit 520 is not influenced as the signal path is thefirst capacitor C1 in series with the operation object and the secondcapacitor C2. Moreover, as the first capacitor C1 has largercapacitance, the capacitance-exciting signal Vs can be more effectivelysent from the first specific conductor Sz1 to the operation object.Besides, the auxiliary capacitance-exciting signal driver circuit 550applies the auxiliary capacitance-exciting signal Vs1 to the selectedtouch sensing electrode E4 (Es) to further enhance the preciseness ofthe hovering or touch sensing operation. In this embodiment, theauxiliary capacitance-exciting signal Vs1 may have the same phase oropposite phase with the capacitance-exciting signal Vs; the frequency ofthe auxiliary capacitance-exciting signal Vs1 may be the same ordifferent with the frequency of the capacitance-exciting signal Vs; theamplitude of the auxiliary capacitance-exciting signal Vs1 may be thesame or different with the amplitude of the capacitance-exciting signalVs. According to one possible implementation, the frequency of theauxiliary capacitance-exciting signal Vs1 is smaller than the frequencyof the capacitance-exciting signal Vs. According to another possibleimplementation, the amplitude of the auxiliary capacitance-excitingsignal Vs1 is smaller than the amplitude of the capacitance-excitingsignal Vs. According to still another possible implementation, the phaseof the auxiliary capacitance-exciting signal Vs1 is opposite to thephase of the capacitance-exciting signal Vs.

Moreover, with reference to FIG. 5A, during the hovering or touchsensing operation, there is only one physical connection point betweenthe touch control circuit 50 and the system circuit 60, namely, a singleconnection point connected to the first specific conductor Sz1, and thetouch control ground 502 and the system ground 602 are differentgrounds. Therefore, there is no common current loop between the touchcontrol circuit 50 and the system circuit 60 during the hovering ortouch sensing operation of the hovering and touch sensing apparatus 10.Moreover, the measurement of the touch control circuit 50 will not beinfluenced by the noise from the system circuit 60. The system powersource 600 has larger capacity to supply electric power to the pixelelectrode 172, the common electrode layer 106, and the thin filmtransistors 174 shown in FIG. 9 or the backlight unit; therefore, thesystem power source 600 has larger power noise. During the hovering ortouch sensing operation, the noise of the system circuit 60 (includingdisplay circuit) can be prevented from coupling to the touch controlcircuit 50 and from influencing the sensing result of the touch controlcircuit 50 if there is no common current loop between the touch controlcircuit 50 and the system circuit 60.

FIG. 5B shows a block diagram of the hovering and touch sensingapparatus 10 according to still another embodiment of the presentinvention. The embodiment shown in FIG. 5B is similar to that shown inFIG. 5A, but the embodiment shown in FIG. 5B can be dispensed with theauxiliary capacitance-exciting signal source 552, namely, the auxiliarycapacitance-exciting signal source 552 is removed in this embodiment.Besides, the input of the auxiliary capacitance-exciting signal drivercircuit 550 is coupled to the output of the capacitance-exciting signalsource 512 to process the output of the capacitance-exciting signalsource 512 into the auxiliary capacitance-exciting signal Vs1. In thisembodiment, the frequency of the auxiliary capacitance-exciting signalVs1 is the same with the frequency of the capacitance-exciting signalVs; but the amplitude and/or phase of the auxiliary capacitance-excitingsignal Vs1 may be the same or different with the amplitude and/or phaseof the capacitance-exciting signal Vs. According to a possibleimplementation, the amplitude of the auxiliary capacitance-excitingsignal Vs1 is smaller than the amplitude of the capacitance-excitingsignal Vs. According to another possible implementation, the phase ofthe auxiliary capacitance-exciting signal Vs1 is opposite to the phaseof the capacitance-exciting signal Vs. Namely, the auxiliarycapacitance-exciting signal driver circuit 550 is an invertingamplifier. Similarly, the auxiliary capacitance-exciting signal drivercircuit 550 applies the auxiliary capacitance-exciting signal Vs1 to theselected touch sensing electrode E4 (Es) to further enhance thepreciseness of the hovering or touch sensing operation.

FIG. 6 shows a block diagram of the hovering and touch sensing apparatus10 according to another embodiment of the present invention. Thehovering and touch sensing apparatus 10 in FIG. 6 is similar to thatshown in FIG. 5B; however, the hovering and touch sensing apparatus 10in FIG. 6 further comprises a DC power source 530 and two switches 532and 534, where the ground of the DC power source 530 is also the touchcontrol ground 502. During hovering or touch sensing operations, the twoswitches 532 and 534 are operated to turn on or off such that a DCvoltage is applied to a second specific conductor Sz2. The secondspecific conductor Sz2 is a conductor different with the first specificconductor Sz1 and structurally placed between the first specificconductor Sz1 and the touch sensing electrode layer 102. With referencealso to FIG. 9, if the first specific conductor Sz1 is the metalliccasing 200 or the conductive coating 200′ of the casing, then the secondspecific conductor Sz2 may be the shielding protective layer 204 of thedisplay or the common electrode layer (common anode or common cathode)106 of OLED display. If the first specific conductor Sz1 is theshielding protective layer 204 of the display, then the second specificconductor Sz2 may be the common electrode layer 106 of OLED display.With reference also to FIG. 11, if the first specific conductor Sz1 isthe metallic casing 200 or the conductive coating 200′ of the casing,then the second specific conductor Sz2 may be the static shieldingprotective layer 150 of the display or the common electrode layer 106 ofLCD. If the first specific conductor Sz1 is the common electrode layer106 of LCD, then the second specific conductor Sz2 may be the staticshielding protective layer 150 of the display. The second specificconductor Sz2 is structurally placed between the first specificconductor Sz1 and the touch sensing electrode layer 102. If a DC voltageis applied to the second specific conductor Sz2, the direct signalcoupling between the first specific conductor Sz1 and the selected touchsensing electrode Es can be blocked to enhance the preciseness forhovering or touch sensing operations. According to another possibleimplementation of the present invention, the second specific conductorSz2 may be electrically connected with the touch control ground 502.Namely, by cutting off the switch 532 and conducting the switch 534, thesecond specific conductor Sz2 is electrically connected to the touchcontrol ground 502 such that the direct signal coupling between thefirst specific conductor Sz1 and the selected touch sensing electrode Escan be blocked to enhance the preciseness for hovering or touch sensingoperations.

FIG. 7 shows a block diagram of the hovering and touch sensing apparatus10 according to still another embodiment of the present invention. Thehovering and touch sensing apparatus 10 in FIG. 7 is similar to thatshown in FIG. 5B; however, the hovering and touch sensing apparatus 10in FIG. 7 further comprises an amplifier with gain larger than zero(namely, non-inverting amplifier) 540. The input of the amplifier 540with gain larger than zero is coupled to the selected touch sensingelectrode Es and the capacitance-sensing signal receiving circuit 520,while the output of the amplifier 540 with gain larger than zero iscoupled to the surrounding touch sensing electrodes Em arranged aroundthe selected touch sensing electrode Es. The amplifier 540 with gainlarger than zero receives the touch sensing signal Vc and non-invertingamplifies the touch sensing signal Vc to form an auxiliary signal Va forpreventing signal coupling. The amplifier 540 with gain larger than zerofurther applies the auxiliary signal Va to the surrounding touch sensingelectrodes Em arranged around the selected touch sensing electrode Essuch that the coupling signal from user finger (or stylus) can beprevented from coupling to the selected touch sensing electrode Esthrough the surrounding touch sensing electrodes Em (which are not thetarget for measurement), thus prevent the coupling signal frominfluencing the measurement for the selected touch sensing electrode Es.Besides above way to apply the auxiliary signal Va, the touch controlcircuit 50 may send a zero-level signal or a DC signal to thesurrounding touch sensing electrodes Em arranged around the selectedtouch sensing electrode Es. Similarly, the coupling signal from userfinger (or stylus) can be prevented from coupling to the selected touchsensing electrode Es through the surrounding touch sensing electrodesEm, thus prevent the coupling signal from influencing the measurementfor the selected touch sensing electrode Es. In this situation, theamplifier 540 with gain larger than zero (non-inverting amplifier 540)can be replaced by an amplifier with gain equal to zero to provide thezero-level signal.

FIG. 8 shows a block diagram of the hovering and touch sensing apparatus10 according to still another embodiment of the present invention. Thehovering and touch sensing apparatus 10 in FIG. 8 is similar to thatshown in FIG. 6; however, the hovering and touch sensing apparatus 10 inFIG. 8 further comprises an amplifier with gain larger than zero(namely, non-inverting amplifier) 540 in comparison with the embodimentshown in FIG. 6. Similarly, the input of the amplifier 540 with gainlarger than zero is coupled to the selected touch sensing electrode Esand the capacitance-sensing signal receiving circuit 520, while theoutput of the amplifier 540 with gain larger than zero is coupled to thesurrounding touch sensing electrodes Em arranged around the selectedtouch sensing electrode Es. When the hovering and touch sensingapparatus 10 performs hovering or touch sensing operations, thecapacitance-exciting signal source 512 of the touch control circuit 50generates an alternating signal and the alternating signal is processedby the capacitance-exciting signal driver circuit 510 to form thecapacitance-exciting signal Vs. The touch control circuit 50 sends thecapacitance-exciting signal Vs to the first specific conductor Sz1 suchthat a first capacitor C1 is formed between the first specific conductorSz1 and the operation object. Moreover, a second capacitor 2 is formedbetween the operation object and the respective touch sensing electrode.The capacitance-sensing signal receiving circuit 520 then receives(reads) a touch sensing signal Vc from the selected touch sensingelectrode Es. At this time, the DC power source 530 supplies a DCvoltage to the second specific conductor Sz2. The second specificconductor Sz2 is a conductor different with the first specific conductorSz1 and structurally placed between the first specific conductor Sz1 andthe touch sensing electrode layer 102. The direct signal couplingbetween the first specific conductor Sz1 and the selected touch sensingelectrode Es can be blocked to enhance the preciseness for hovering ortouch sensing operations. The amplifier 540 with gain larger than zeroreceives the touch sensing signal Vc and non-inverting amplifies thetouch sensing signal Vc to form an auxiliary signal Va for preventingsignal coupling. The amplifier 540 with gain larger than zero furtherapplies the auxiliary signal Va to the surrounding touch sensingelectrodes Em arranged around the selected touch sensing electrode Essuch that the coupling signal from user finger (or stylus) can beprevented from coupling to the selected touch sensing electrode Esthrough the surrounding touch sensing electrodes Em, thus prevent thecoupling signal from influencing the measurement for the selected touchsensing electrode Es.

In the embodiments shown in FIGS. 6˜8, they are similar to that shown inFIG. 5B, namely only the capacitance-exciting signal source 512 ispresent (in other words, the auxiliary capacitance-exciting signal Vs1is output by the capacitance-exciting signal source 512 afterprocessing). However, similar to the embodiment shown in FIG. 5A, theembodiments shown in FIGS. 6˜8 can be adapted to have additionalauxiliary capacitance-exciting signal source 552 to generate anotheralternating signal and the auxiliary capacitance-exciting signal drivercircuit 550 processes the another alternating signal to provide theauxiliary capacitance-exciting signal Vs1. If the embodiments shown inFIGS. 6˜8 use additional auxiliary capacitance-exciting signal source552 to provide the auxiliary capacitance-exciting signal Vs1, theauxiliary capacitance-exciting signal Vs1 may have the same phase oropposite phase with the capacitance-exciting signal Vs; the frequency ofthe auxiliary capacitance-exciting signal Vs1 may be the same ordifferent with the frequency of the capacitance-exciting signal Vs; theamplitude of the auxiliary capacitance-exciting signal Vs1 may be thesame or different with the amplitude of the capacitance-exciting signalVs. According to one possible implementation, the frequency of theauxiliary capacitance-exciting signal Vs1 is smaller than the frequencyof the capacitance-exciting signal Vs. According to another possibleimplementation, the amplitude of the auxiliary capacitance-excitingsignal Vs1 is smaller than the amplitude of the capacitance-excitingsignal Vs. According to still another possible implementation, the phaseof the auxiliary capacitance-exciting signal Vs1 is opposite to thephase of the capacitance-exciting signal Vs.

Besides, in the embodiments shown in FIGS. 5B, 6˜8, during the hoveringor touch sensing operation, there is only one physical connection pointbetween the touch control circuit 50 and the system circuit 60, namely,a single connection point connected to the first specific conductor Sz1,and the touch control ground 502 and the system ground 602 are differentgrounds. Therefore, there is not common current loop between the touchcontrol circuit 50 and the system circuit 60 during the hovering ortouch sensing operation of the hovering and touch sensing apparatus 10.Moreover, the measurement of the touch control circuit 50 will not beinfluenced by the noise from the system circuit 60. Besides, a groundimpedance Z1 is present between the first specific conductor Sz1 and thesystem ground 602, and the ground impedance Z1 is for example, animpedance smaller than one hundred thousand of ohms or zero-ohmimpedance.

FIG. 12A shows a layered structure of the hovering and touch sensingapparatus 10 according to an embodiment of the present invention. Thehovering and touch sensing apparatus 10 shown in this embodimentcomprises a touch display panel formed by attaching a touch controlpanel 300 to a display 400 and arranging the touch display panel on acasing 200. The display 400 may be a liquid crystal display or an OLEDdisplay. FIGS. 12B, 12C and 12D respectively show the layered structuresfor the touch control panel 300 according to different embodiments ofthe present invention. As shown in FIG. 12B, the touch control panel 300comprises, from top to down, a protection layer 100 and a touch sensingelectrode layer 102. The protection layer 100 is a glass substrate or apolymer substrate, and the touch sensing electrode layer 102 comprises aplurality of transparent conductive electrodes. With reference also toFIGS. 9 and 11, the uppermost two layers shown in these two figures canbe the structure shown in FIG. 12B. In other possible implementations,the uppermost two layers shown in the embodiments of FIGS. 9 and 11 canbe replaced by the touch control panel 300 shown in FIGS. 12C and 12D.The touch control panel 300 shown in FIG. 12C comprises, from top todown, a protection layer 100, a touch sensing electrode layer 102 (whichcan be deemed as the first transparent conductive layer), a firstinsulating layer 1031, and a second transparent conductive layer 1051.

The touch control panel 300 shown in FIG. 12D comprises, from top todown, a protection layer 100, a touch sensing electrode layer 102 (whichcan be deemed as the first transparent conductive layer), a firstinsulating layer 1031, and a second transparent conductive layer 1051, asecond insulating layer 1032 and a third transparent conductive layer1052.

With reference to FIGS. 1, 3, 5A, 5B and 7, when the uppermost twolayers of the hovering and touch sensing apparatus 10 shown in FIGS. 9and 11 are replaced by the touch control panel 300 shown in FIG. 12C,the first specific conductor Sz1 can be the second transparentconductive layer 1051 shown in FIG. 11C.

With reference to FIGS. 2, 4, 6 and 8, when the uppermost two layers ofthe hovering and touch sensing apparatus 10 shown in FIG. 9 are replacedby the touch control panel 300 shown in FIG. 12C, the second specificconductor Sz2 can be the second transparent conductive layer 1051 whilethe first specific conductor Sz1 can be the common electrode layer 106,the metallic casing 200 or the conductive coating 200′ of a casing.

when the uppermost two layers of the hovering and touch sensingapparatus 10 shown in FIG. 11 are replaced by the touch control panel300 shown in FIG. 12C, the second specific conductor Sz2 can be thesecond transparent conductive layer 1051 while the first specificconductor Sz1 can be the static shielding protective layer 150, thecommon electrode layer 106, the metallic casing 200 or the conductivecoating 200′ of a casing.

With reference to FIGS. 2, 4, 6 and 8, when the uppermost two layers ofthe hovering and touch sensing apparatus 10 shown in FIGS. 9 and 11 arereplaced by the touch control panel 300 shown in FIG. 12D, the secondspecific conductor Sz2 can be the second transparent conductive layer1051 while the first specific conductor Sz1 can be the third transparentconductive layer 1052.

In above mentioned embodiments, the plurality of touch sensingelectrodes and the second specific conductor Sz2 can be made fromtransparent conductive material. The capacitance-sensing signalreceiving circuit 520 can be self-capacitance sensing circuit.

To sum up, the hovering and touch sensing apparatus of the presentinvention has at least following advantages:

1. During hovering or touch sensing operation, the hovering and touchsensing apparatus applies an alternating signal, which is driven by thecapacitance-exciting signal driver circuit, to the first specificconductor. The first specific conductor is, for example, a metalliccasing, a conductive coating of a casing, a static shielding protectivelayer, a shielding protective layer, or a common electrode layer of adisplay, thus more effectively apply the capacitance-exciting signal tothe operation object.

2. During hovering or touch sensing operation, there is only onephysical connection point between the touch control circuit 50 and thesystem circuit 60, and the touch control ground 502 and the systemground 602 are different grounds. Therefore, there is no common currentloop between the touch control circuit 50 and the system circuit 60during the hovering or touch sensing operation of the hovering and touchsensing apparatus 10. Moreover, the measurement of the touch controlcircuit 50 will not be influenced by the noise from the system circuit60.

Although the present invention has been described with reference to theforegoing preferred embodiment, it will be understood that the inventionis not limited to the details thereof. Various equivalent variations andmodifications can still occur to those skilled in this art in view ofthe teachings of the present invention. Thus, all such variations andequivalent modifications are also embraced within the scope of theinvention as defined in the appended claims.

What is claimed is:
 1. A hovering and touch sensing apparatus withauxiliary capacitance-exciting signal, the hovering and touch sensingapparatus comprising: a touch sensing electrode matrix comprising aplurality of touch sensing electrodes, a system circuit and a touchcontrol circuit; the system circuit comprising: a system power source; asystem ground; a first specific conductor with area larger than any areaof the touch sensing electrodes, the first specific conductorelectrically connected to the system power source and the system ground;the touch control circuit comprising: a touch control power source; atouch control ground; a capacitance-exciting signal source; acapacitance-exciting signal driver circuit; an auxiliarycapacitance-exciting signal driver circuit and at least onecapacitance-sensing signal receiving circuit, wherein the touch controlpower source is electrically connected to the touch control ground andsupplies electric power to the capacitance-exciting signal source, thecapacitance-exciting signal driver circuit, the auxiliarycapacitance-exciting signal driver circuit and the at least onecapacitance-sensing signal receiving circuit, wherein when an operationobject approaches or touches the plurality of touch sensing electrodesfor hovering or touch sensing operation, there is no common current loopbetween the system power source and the touch control power source; thecapacitance-exciting signal source generates an alternating signal; thecapacitance-exciting signal driver circuit processes the alternatingsignal and then electrically coupled the processed alternating signal tothe first specific conductor, the auxiliary capacitance-exciting signaldriver circuit generates an auxiliary capacitance-exciting signal andapplies the auxiliary capacitance-exciting signal to a selected touchsensing electrode; wherein a first capacitor is formed between theoperation object and the first specific conductor, a second capacitor isformed between the operation object and the respective one of the touchsensing electrodes, the at least one capacitance-sensing signalreceiving circuit receives a touch sensing signal from the selectedtouch sensing electrode.
 2. The hovering and touch sensing apparatus inclaim 1, wherein a ground impedance with resistance less than onehundred thousand of ohms is arranged between the first specificconductor and the system ground.
 3. The hovering and touch sensingapparatus in claim 1, wherein the alternating signal generated by thecapacitance-exciting signal source is a sinusoid wave signal, a squarewave signal, a triangular wave signal or a trapezoid wave signal.
 4. Thehovering and touch sensing apparatus in claim 1, wherein a capacitanceof the first capacitor is larger than a capacitance of the secondcapacitor during hovering or touch sensing operation.
 5. The hoveringand touch sensing apparatus in claim 1, further comprising an amplifierwith gain larger than zero, wherein the amplifier with gain larger thanzero processes the touch sensing signal into an auxiliary signal andapplies the auxiliary signal to a plurality of touch sensing electrodesarranged around the selected touch sensing electrode.
 6. The hoveringand touch sensing apparatus in claim 1, wherein the touch controlcircuit further applies a zero level signal or a DC signal to aplurality of touch sensing electrodes arranged around the selected touchsensing electrode.
 7. The hovering and touch sensing apparatus in claim1, wherein an amplitude of the auxiliary capacitance-exciting signal issmaller than an amplitude of the capacitance-exciting signal.
 8. Thehovering and touch sensing apparatus in claim 1, wherein the auxiliarycapacitance-exciting signal driver circuit sends the auxiliarycapacitance-exciting signal to the selected touch sensing electrodethrough an impedance.
 9. The hovering and touch sensing apparatus inclaim 1, wherein the system circuit comprises a display driver and thefirst specific conductor is a static shielding protective layer or ashielding protective layer of a display.
 10. The hovering and touchsensing apparatus in claim 1, wherein the system circuit comprises adisplay driver and the first specific conductor is a common electrodelayer of a display.
 11. The hovering and touch sensing apparatus inclaim 1, wherein the first specific conductor is a metallic casing or aconductive coating of a casing.
 12. The hovering and touch sensingapparatus in claim 1, further comprising a second specific conductorarranged between the first specific conductor and the touch sensingelectrode matrix.
 13. The hovering and touch sensing apparatus in claim12, wherein the second specific conductor is electrically connected tothe touch control ground during hovering or touch sensing operation. 14.The hovering and touch sensing apparatus in claim 12, wherein the touchcontrol circuit applies a DC voltage to the second specific conductorduring hovering or touch sensing operation.
 15. The hovering and touchsensing apparatus in claim 1, wherein the auxiliary capacitance-excitingsignal driver circuit receives the alternating signal and processes thealternating signal into the auxiliary capacitance-exciting signal. 16.The hovering and touch sensing apparatus in claim 1, further comprisingan auxiliary capacitance-exciting signal source, wherein the auxiliarycapacitance-exciting signal source generates another alternating signaland sends the another alternating signal to the auxiliarycapacitance-exciting signal driver circuit to generate the auxiliarycapacitance-exciting signal.
 17. The hovering and touch sensingapparatus in claim 16, wherein a frequency of the auxiliarycapacitance-exciting signal is smaller than a frequency of thecapacitance-exciting signal.
 18. The hovering and touch sensingapparatus in claim 16, wherein a phase of the auxiliarycapacitance-exciting signal is opposite to a phase of thecapacitance-exciting signal.
 19. The hovering and touch sensingapparatus in claim 1, wherein the capacitance-sensing signal receivingcircuit is a self-capacitance sensing circuit.